DE660484C - Rotary lobe pump for drip liquid means, which has a sickle-shaped working space and working chambers, which open into suction and pressure spaces arranged within the working chambers - Google Patents

Description

The invention relates to a rotary lobe pump for liquid working medium with drip sickle-shaped working space and working chambers opening into common suction and pressure spaces, in which the suction and pressure chambers for the purpose of changing the conveying capacity and conveying direction compared to the crescent-shaped workspace can be relocated. The suction and pressure spaces can be inside or outside of the work area. In the case of pumps, the former Art, the invention is characterized by a rotatable partition between the suction and pressure chambers, their position in relation to the sickle-shaped working chamber for the purpose of changing the delivery rate and the direction of flow of the pump is variable. In the case of pumps of the latter type, the Invention characterized by two rotatable, mutually opposite and with each other connected partition walls between the suction and pressure space. By corresponding rotation of the steady state fixed partition or partition walls, a change in the conveying capacity and conveying direction can be achieved in a simple manner without any disadvantages in terms of filling the working spaces or throttling losses result.

• 30 Furthermore, according to the invention, the inlet and outlet openings of the suction and Pressure chambers opposite one another in the layers of the partition wall or partition walls be arranged, which correspond to the greatest delivery rate of the pump. Will the proposed design for fluid transmissions of known type with a central flow channel applied, it is only necessary to regulate the otherwise fixed partition or to rotate partitions.

Figs. 1 to 5 of the drawing show embodiments of the invention. In them mean:

α and U ₁ impellers, b and O ₁ their wings, c the connecting channels between the individual cells and the suction and pressure chambers and e fixed cell walls.

In Fig. 1, the suction and pressure spaces within the impeller α and the connecting channels c are provided in this; in Figs. 2 and 3 they enclose the impeller a, and the cell wall e is perforated for their connection with the individual cells.

For the designs according to Fig.-i and 2, with the position of the partition walls d shown, and when the impeller α moves clockwise, there is the greatest delivery rate in the sense indicated by the arrows. If the partitions d are rotated clockwise and thus the suction and pressure spaces are displaced in a circle with respect to the cells, which remain unchanged, the delivery rate decreases steadily and steadily as an increasing balance between the

Suction and pressure cells arise until in the middle position of the partitions rf, which is indicated in Fig. Because the openings of the suction and pressure chambers are arranged opposite at the end positions of the TreW walls rf and not in the middle position, when the partition walls rf are rotated beyond the middle position, a ίο promotion in the opposite direction begins in the end position opposite to the starting position the partition walls d reached their maximum size.

A change in the delivery rate is also possible if, in contrast to FIGS. 1 and 2, the outlet openings of the suction and pressure spaces are connected to the partition walls d . For example, are the partition walls in Fig. 2? Just as the suction and pressure ports are firmly connected to the outer housing wall, when these parts are adjusted together around the fixed housing wall e, the effect of the device on the delivery rate remains basically the same as if the partition walls d alone between the two Housing walls are adjusted. The lines connected to the suction and pressure ports then only have to be designed to be movable.

With the constant change in the delivery rate 'and with the reversal of the direction of funding are the two main conditions for the proper design of fluid gears Fulfills. This otherwise known way consists of a pump part and a prime mover, so can pump or prime mover or both after the Invention be set up.

A particularly simple example of such a fluid transmission is given in FIGS. 3 to 5, in which the rotary lobe pump and rotary lobe engine enclose one another. Here the unchangeable partitions d serving the regulation are combined into an unchangeable ring (control ring), which is movable in a circle, inwardly according to Fig. 2 the control means for the suction and pressure chambers of the - pump «, b, e forms and after serves as an abutment on the outside of the spool B _{1 of} the engine.

When adjusting the control ring d , the slide pistons O _{1 are} inevitably pushed in and out so that they remain in permanent contact with the outer control ring surface, i.e. their axis of symmetry moves in a circle with the control ring, while the pump cells remain unchanged because their housing is fixed. The transmission thus represents the combination of a pump corresponding to the invention according to FIG. 2 with a prime mover, the cells of which do not remain unchanged when the gear ratio changes.

In the position shown in Fig. 3 partitions d of the control ring and at

running the pump clockwise results

: h für.das KraftmaschinenradOt ₁ the highest possible number of revolutions in the direction of rotation opposite to the pump wheel e; this number of revolutions decreases steadily and steadily when the control ring rf is turned, in order to be ^{equal to zero at 90 0} rotation angle, and increases steadily to a maximum value in the opposite direction of rotation when the control ring rf is turned further up to about 180 °.

Is shown in Fig. 4 of the partition walls rf containing control ring in a position illustrated which is twisted to the position shown in Fig. 3 to about 1:35 ^0, whereby the counter-rotation with the utmost translation changes in a constant velocity medium translation. In Fig. 5, which is a section along the line ABC of Fig. 4, it is shown, for example, how the control ring d can be adjusted and held in a certain position by a toothed segment / 2 connected to it, into which a gearwheel / on shaft g intervenes. "'

The representation of the cell spaces and cell wings in Figs. 1 to 5 is only an example given; for their training as piston, vane or wheel cells each is with such rotary piston machines conventional arrangement possible. The discussions apply analogously for rotary lobe engines as for rotary lobe pumps.

Claims (5)

Patent claims: 1. Rotary lobe pump for drip liquids that have a sickle-shaped design Has working space and working chambers, which are arranged in suction or Pressure rooms! open, characterized by a rotatable partition (rf) zwisehen the suction and pressure chambers, their position in relation to the sickle-shaped working chamber for the purpose of changing the Delivery rate and the delivery device of the pump is variable. 2. Rotary lobe pump for drip liquids, which has a sickle-shaped working space and working chambers has, which open into suction or pressure chambers arranged outside the working chambers, characterized by two rotatable, opposing and interconnected Partition walls (rf, rf) between the suction and pressure space. 3. Rotary lobe pump according to claim 1 or 2, characterized in that the Alles Inlet and outlet openings of the suction and Pressure chambers arranged opposite one another in the layers of the partition walls which correspond to the greatest delivery rate. 4. Fluid transmission in an otherwise known manner from pump and engine consisting, characterized in that the pump or the engine or both according to claim 1 or claim 2 are trained. 5. Fluid transmission in which the pump and prime mover enclose each other, characterized in that the partition walls are arranged according to claim 2 between the pump and the engine. For this purpose ι sheet of drawings